BEHAVIOR OF DOXORUBICIN INVESTIGATED BY FLUORESCENCE SPECTROSCOPY

Hoai Viet Nguyen

Reg.č.projektu: CZ.1.07/2.3.00/20.0148

Název projektu: Mezinárodní spolupráce v oblasti "in vivo" zobrazovacích technik

Název:

Školitel:

Datum:14.06.2013

Contents

INTRODUCTION1

EXPERIMENTAL SECTION2

RESULT AND DISCUSSION3

CONCLUSION4

LUMINESCENCE

Chemiluminescence1

Crystalloluminescence1

Electroluminescence1

Mechanoluminescence1

Photoluminescence1

Radioluminescence1

Sonoluminescence1

Thermoluminescence1

PHOTOLUMINESCENCE

• Phosphorescence

• Fluorescence

Fig. 1: Jablonski diagram describing the electronic levels of molecules andpossible transitions between different singlet and triplet states.

T1

FLUORESCENCE• Light emitted by singlet excited states of molecules following absorption from

an external resourse.

• Requirement for fluorophore: A molecule with a rigid conjugated structure (usually a polyaromatic hydrocarbon or heterocylce).

Naphthalene Pyridine

FLUORESCENCE• Many factors influence on fluorescence

properties:- Viscosity (proportional)- Temperature (inversely proportional)- Solvent- pH of solution- Concentration of fluorophore

• Application on mineralogy, gemology, and chemical sensors in fluorescence spectroscopy.

FLUORIMETRIC ANALYSIS- Measurements preformed by multifunctional microplate reader Tecan Infinite 200PRO (Tecan, Switzerland)

- Sample were placed in transparent 96 well microplate with flat bottom by Nunc (ThermoScientific, USA)

- Fluorescene was measured with λex=480nm and λem was in the range of 510nm to 850nm per 5nm steps. Each value is avarage of 5 measurements

- Solutions of 20 mM sodium acetate (pH 4, 5), 20 mM sodium phosphate (pH 6, 7, 8), 20 mM sodium borate (pH 9, 10), ethanol (EtOH) (10, 20, 30, 50, 70, 100%), acetonitrile (ACN) (10, 20, 30, 50, 70%), and dimethyl sulfoxide (DMSO) (10, 20, 30, 50, 70, 100%) were used. Solutions of different concentration of DOX (1-500µg/ml) were analysed.

STRUCTURE OF DOXORUBICIN

RESULT AND DISCUSSION

Fig. 2: Fluorescence intensity in the emission maxima of DOX 125 µg/ml under various pH. Solutions of 20 mM sodium acetate (pH 4, 5), 20 mM sodium phosphate (pH 6, 7, 8), 20 mM sodium borate (pH 9, 10) were used.

Fig. 1: Emission spectra (λex = 480 nm) of DOX under various pH. Solutions of 20 mM sodium acetate (pH 4, 5), 20 mM sodium phosphate (pH 6, 7, 8), 20 mM sodium borate (pH 9, 10) were used.

RESULT AND DISCUSSION

Fig. 4: Fluorescence intensity in the emission maxima of DOX (125µg/ml) dissolved in EtOH.

Fig. 3: Emission spectra (λex = 480 nm) of DOX (125µg/ml) dissolved in EtOH.

RESULT AND DISCUSSION

Fig. 6: Fluorescence intensity in the emission maxima of DOX (125µg/ml) dissolved in ACN.

Fig. 5 Emission spectra (λex = 480 nm) of DOX (125µg/ml) dissolved in ACN.

RESULT AND DICUSSION

Fig. 8: Fluorescence intensity in the emission maxima of DOX (125µg/ml) dissolved in DMSO.

Fig. 7: Emission spectra (λex = 480 nm) of DOX (125µg/ml) dissolved in DMSO.

CONSLUSION

• Fluorimetry is the suitable method for the analysis of DOX under various conditions.

• Based on the results can be concluded that fluorescence of DOX depends on the pH of solution.

• Fluorescence intensity of DOX dissolved in organic solvents is higher than DOX is dissolved in inorganic solvents.

THANKS TO

• Ing. Maja Stanisavljević• Mgr. Marketa Vaculovicova PhD• Prof. Ing.Rene Kizek PhD• CYTORES GA ČR P301/10/0356, PGS16_2012